KR20060118930A - Linear AC Power Control Device Using Phase Comparison Control - Google Patents

Abstract

A linear AC(Alternating Current) power control device using phase comparison control is provided to supply proper power by using a mutual induction reactor as small as about 1/10 of load power and to supply a favorable average AC voltage by double phase control or linear voltage control. In a linear AC power control device using phase comparison control, a phase comparison controller(1), a voltage varying autotransformer(2), and a voltage decompressing mutual induction reactor(3) are installed at the power input side. The mutual induction reactor is connected to a switch array(7) by installing a multi-stage tap to the autotransformer. Voltage and current comparators(4,5) are mounted at the power output side. A logic controller(6) is installed at each output side of the output voltage comparator and the current comparator and the output side of the phase comparison controller. Therefore, a proper voltage is set at the load side by selectively applying the output voltage of the autotransformer to the mutual induction reactor by operating the switch array by the logic controller.

Description

Linear AC power control device using phase comparison control

1 is a block diagram of a power control apparatus according to the present invention

2 is an explanatory diagram of a power control output waveform of the present invention. FIG. 7A is a linear control output waveform diagram and FIG. 7B is a phase control output waveform diagram.

<Explanation of symbols for main parts of drawing>

DESCRIPTION OF SYMBOLS 1 Phase comparison controller 2 Single winding transformer 21 Top side 22 Bottom side 3 Inductive reactor 31 Voltage coil 32 Current coil 4 Voltage comparator 41 Voltage variable tap 42 Input voltage comparison detector 43 Voltage level selector 5 Current Comparator 6 Logic Controller 7 Switch Array 71 Switch 16: Zero Crossing Controller 17 OR Logic Circuit 18 Current Check CT 8 Load 81 Bypass Switch 82 Magnetic 83 Resistance 100 Power

The present invention relates to an AC power conversion and control apparatus of a linear control method using an electromagnetic conversion means such as a transformer. Particularly, when a required voltage is set on the load side, a pressure reduction function and a constant voltage function for maintaining the output voltage constant even if the input voltage changes. In addition, the present invention relates to a linear AC power control device using phase comparison control with an uninterrupted bypass function.

Conventional AC power control and conversion devices include linear voltage conversion devices such as single-phase, lottery-type transformers and reactors, and power control devices by phase control or PWM control using switching semiconductor elements, but general transformers. The power control device of the type is too low in practicality because the volume and weight are too large, and the power control device of the switching control method using electronic circuits is not durable, reliable, and economical, and EMI problems that hinder the surrounding electrical environment are a problem. Has been.

Among the conventional linear control methods, the British patent (GB2043971A) `` constant voltage control device '' is based on the primary coil polarity switching switching system, which does not allow delicate constant voltage control, and when the primary coil is disconnected and the primary side is not excited, The secondary side coils connected in series can all be converted into circuit resistances and cause overheating due to heat loss.

Also, if the primary coil circuit switch is closed and closed, the load current flows through the secondary coil, and the current induced in the primary coil generates heat by itself and the power loss increases. In addition, such control method generates an instantaneous counter voltage and a transient phenomenon, and when the load is an electronic product (COMPUTER, AUDIO, TV, etc.), it provides considerable electromagnetic noise to the load side. Electronic products, which are other load conditions besides the load, are subject to restrictions on use, and the power failure may be caused by sudden power changes during bypass, which affects the load a lot.

Accordingly, an object of the present invention is to provide a phase comparison controller 1, a voltage variable single winding transformer 2, and a voltage decompression mutual induction reactor 3 at a power input in solving the above problems, but in a single winding transformer 2. Install a multi-stage tap to connect the mutual induction reactor (3) to the switch array (7), install a voltage and current comparator at the power output, and compare the output and phase of the output voltage comparator (4) and current comparator (5) Since the logic controller 6 is installed at the output of the controller 1 to operate the switch array 7 by the logic controller 6 to selectively apply the output voltage of the single winding transformer 4 to the mutual induction reactor 3. By setting the required voltage on the load side, a constant voltage control device with a function of keeping the output voltage constant even if the input voltage changes is provided, and a voltage reduced by about 10 to 20% is sufficient even if the voltage is applied to the load side. In addition, in the case of an electric product that performs its functions effectively, it is possible to perform a power-saving function by stably supplying a reduced voltage, and it is possible to perform a large capacity by using only a single winding transformer and a mutual induction reactor of about 1/10 of the load capacity. It can control the load power, have stable constant voltage function against input voltage fluctuation, or have the means to change the output voltage manually, and can bypass input power automatically according to the circumstances of the load side, In order to provide a linear power control device and a configuration method which can minimize the control loss, a variable single winding transformer connected in parallel to the power input is applied with a small current voltage to the primary side of the phase induction reactor, The secondary side current coil is obtained by obtaining a load output decompressed by the secondary side current coil voltage. It has the means to change the voltage by the change of the primary side voltage, and the automatic voltage regulation and the uninterruptible bypass are possible by using the above means for the input voltage and the output voltage fluctuation, so that there is little power failure or power with little EMI or switching noise. To provide a control device

As shown in FIG. 1 of the accompanying drawings, a phase comparison controller 1, a voltage variable single winding transformer 2, and a voltage decompression mutual induction reactor 3 are provided at a power input, The voltage comparator 4 and the current comparator 5 are provided, and the logic controller 6 is provided at the output of the output voltage comparator 4 and the current comparator 5 and the phase comparator 1, and the logic controller 6 is provided. By operating the switch array (7) by a), by selectively applying the modified output voltage through the single winding transformer (2) or the bypass voltage not passing through the single winding transformer (2) to the mutual induction reactor (3) The output voltage of the mutual induction reactor 3 can be adjusted, and the secondary current coil 32 of the mutual induction reactor 3 connects one end of the winding to a power source and the other end of the winding to the load (8). ) In series. This means that the primary side voltage coil 31 and the secondary side current coil 32 of the mutual induction reactor 3 are connected in phase with each other. The voltage varying means may constitute this with the variable tap 41.

Since the current coil winding 32 is wound in phase with respect to the voltage coil 31, the mutual induction reactor 3 configured as described above outputs about 10% of the power supply voltage to supply the load 8 to the load 8 side. V ₂ ) = power supply voltage (Vs)-current coil voltage (Vx), so the current coil (32) voltage (V _x ) need only winding a coil corresponding to 10% of the power supply voltage (Vs), and the mutual induction reactor ( The capacity of 3) is determined by the current I _L x the current coil voltage Vx flowing in the load, which is about 1/10 of the power capacity to be supplied to the load 8. That is, the current coil voltage Vx is determined by the ratio of the winding n of the primary side voltage coil 31 and the current coil winding n ₂ and the voltage of the primary side voltage coil 31, so that the primary side voltage coil ( When a voltage is applied to 31, the input power supply voltage Vs is attenuated by the current coil voltage Vx and applied to the load 8.

However, if it is necessary to vary the voltage supplied to the load according to the type of load or the need, it is necessary to tap out the secondary current coil winding (n ₂ ) to adjust the load current amount (IL) so large that the size of the switching device becomes large. The larger the current amount I _L , the more difficult it becomes. And a primary voltage coil winding (n ₁₎ in the if my come adjustment because the amount of current is less increases the practicality of the switching device, but the secondary current coil voltage (Vx) tab, the primary voltage coil to reduce 50% (n ₁₎ The winding has to be wound twice as many times, and again the primary side voltage coil (n ₁ ) has to be wound four times as much to further reduce 50%, which leads to an increase in the amount of winding and leads to the secondary current coil (n ₂ ). Since the amount of current decreases in proportion to the coil winding ratio, it cannot control the load current and also does not function as a normal mutual induction reactor. In addition, if the secondary side current coil voltage (Vx) is increased, the winding of the primary side voltage coil (n ₁ ) should be decreased. In this case, the current increases in the primary side voltage coil (n ₁ ), the efficiency decreases, and the magnetic flux saturation occurs. easy. In the present invention instead of the conventional control method as described above, the secondary side current coil 32 through which a large current flows is fixedly connected to the load 8 in series, and a variable voltage is applied to the primary side voltage coil 31 to provide a secondary side current coil ( The voltage Vx of 32 can be varied. In other words, the capacity of the primary voltage coil (n _1), the secondary current coil (n ₂₎ single winding transformer (2), so that a very small current flow than the electric current with a variable voltage tap connected to the primary voltage coil (n ₁₎ Mutual Like the induction reactor 3, about 1/10 of the load current capacity is sufficient.

Therefore, by applying the continuous variable voltage of the single winding transformer 2 or the tap voltage of several steps to the primary side coil of the mutual induction reactor 3, the load (8) voltage can be controlled in proportion to it and the discontinuous transient is minimized. It is possible to reduce the efficiency, loss and overheating of the mutual induction reactor (3).

The secondary current coil 32 of the mutual induction reactor 3 connects one starting point of the winding to the power source and the other end of the winding to the load 8. The thickness of the secondary side current coil 32 is designed to sufficiently flow the rated current of the load 8, and the winding voltage Vx of the secondary side current coil 32 is 20% or less of the input rated voltage. The voltage varying means of the single winding transformer 2 coupled to the primary side of the mutual induction reactor 3 may be configured with variable taps, but as shown in FIG. 4 of the accompanying drawings, the starting winding of the single winding transformer 2 is shown. Several fixing taps (S0, S1, S2, S3, Sn) from the middle to the middle, install a switch array (7) selectively connected to each fixing tap, and mutually induce a common tap of the switch array (7) It is connected to one side of the primary side voltage coil 31 of the reactor 3, the other side of the primary side voltage coil 31 is connected to the ground common line of the power supply, the winding end lower end (SD) of the single winding transformer (2) It is preferable to connect a separate independent switch 71 and to connect the output terminal of the switch 71 to the common terminal of the switch array (7). Each switch can be configured with elements such as relays or triacs. The secondary side current coil 32 of the mutual induction reactor 3 is connected in series with the load 8.

Since the output voltage (V2) = power supply voltage (Vs)-current coil voltage (Vx), the secondary current coil 32 of the mutual induction reactor (3), the coil corresponding to 10% of the power supply voltage (Vs) to the primary voltage By winding the coil 7 in phase, it is made to reduce the pressure of about 10% of the power supply voltage to supply it to the load 8 side. As such, the current coil 32 may be wound around a coil corresponding to 10% of the power supply voltage Vs, and the capacity of the mutual induction reactor 3 is equal to the current IL of the load 8 and the current coil 32. Since it is determined by the voltage Vx, the capacity of the mutual induction reactor 3 is small enough to be about 1/10 of the capacity of the load 8. The voltage Vx of the secondary current coil 32 is determined by the ratio of the windings of the primary side voltage coil 31 and the windings of the secondary current coil 32 and the voltage of the primary side voltage coil 31. According to the voltage applied to the voltage coil 31, the input power supply voltage Vs is reduced by the current coil voltage Vx and supplied to the load 8, thus reducing the power by Vx X IL.

The output of the phase comparison controller 1 connected in parallel to the power supply is connected to one side of the OR logic controller 6, and the output of the output current comparator 5 comparing the current on the load 8 side is OR logic controller ( Connect to the other side of 6). The output of the OR logic controller 6 is connected to the control input S of the switch 71 and to the control input C which turns off all the switch arrays 7. On the other hand, the output voltage comparator 4 comparing the output voltage V2 supplied to the load side is connected in parallel with the mutual induction reactor 3 output, and the output of the output voltage comparator 4 is switched by the switch array 7. Connect to the control input (S). In addition, a variable resistor for explaining the phase comparison reference voltage is connected to the input of the phase comparison controller 1.

Thus, when power is applied, the phase comparison controller 1 outputs the signal compared by the reference voltage CV in the H or L state. Through the OR logic controller 6, this signal is turned on at the input voltage lower than the reference voltage of the phase comparison controller 1, and the bypass switch 71 is turned on and the switch array 7 is turned off so that the input power is supplied to the output. On the other hand, at the input voltage higher than the reference voltage of the phase comparison controller 1, the bypass switch 71 is turned off and any one of the switch arrays 7 is turned on so that the primary side of the mutual induction reactor 3 is turned on. The output voltage V2 of which the coil 31 is excited and the constant voltage Vx is reduced is supplied to the load.

The phase control output waveform of AC as shown in FIG. 7B can be obtained by the operation of the phase comparison controller 1 and the reference voltage CV. The average voltage of the phase control output is adjusted by the ratio of the bypass direct (D) ON time and the power saving (S) time. In addition, when the input voltage Vs rises above the reference voltage set by the output voltage comparator 4, the switch connection tap of the switch array 7 is selected upward by the output signal of the output voltage comparator 4 so that the mutual induction reactor 3 Increase the secondary current coil voltage (Vx) of to make the output voltage constant. This linear control output waveform is shown in FIG. 7A. When the load current IL flows more than the reference current set by the output current comparator 5, the bypass switch 71 is turned on by the output signal of the output current comparator 5, and the switch array 7 is completely OFF. Therefore, when a load current is required such as when starting a motor, the input power is bypassed immediately to supply sufficient power required by the load. When the normal current is reduced, the bypass switch 71 is turned off and the power saving mode switch array 7 is turned on.

In addition, when the winding start point of the primary side voltage coil 31 of the mutual induction reactor 3 is connected to the upper side 21 of the single winding transformer 2, the voltage Vx of the secondary side current coil 8 becomes the maximum and is cut. The total amount is also maximum. When the primary side voltage core 31 of the mutual induction reactor 3 is connected to the intermediate tap (for example, S3) of the single winding transformer 2, the secondary side current is reduced when the primary side voltage V1 of the mutual induction reactor 3 decreases. The voltage Vx of the coil 32 is also reduced and the amount of power saving is also reduced. Therefore, when the input voltage Vs increases, the intermediate tap S3 may be connected to the higher voltage 21 to keep the output voltage V2 constant. In addition, when it is necessary to supply a high voltage to the load side, such as when starting a motor or turning on a discharge lamp, etc., the winding starting point of the primary side voltage coil 31 is set to the other lower side of the disconnection transformer 2 ( 22) so that the primary coil of the mutual induction reactor 3 forms a short circuit, so that the magnetic flux of the mutual induction reactor 3 is canceled and the current coil 32 of the secondary side turns into a conductor to flow a large current. This allows the input power to be directly supplied to the load 8 without using a separate bypass switch. That is, a separate large-capacity current switch does not need to be connected to both ends of the secondary side current coil 32 of the mutual induction reactor 3, and the single winding transformer 2 can be operated even if the linear voltage variable or the tap-change switching of the primary side coil 31 is performed. Because the closed circuit is formed by parallel circuit of), it is possible to minimize the transient shape such as high voltage surge.

On the other hand, when the input voltage Vs decreases, the voltage drop is compensated by moving toward the middle tap on the upper end side 21 of the winding of the single winding transformer 2, and the input voltage is set by the output voltage comparator 4. When the voltage is lowered below, the intermediate tap is connected to the upper end side of the winding 21 so that the voltage coil 31 and the current coil 32 are connected in parallel, and the magnetic flux is canceled to supply 100% of the power supply voltage to the load 8. do.

By the basic principle and configuration of the present invention as described above will be described in detail the automatic voltage regulation function (constant voltage) and the ability to bypass the input power to the load side.

Connect the single winding transformer 2 in parallel with the power supply 100, make several selective fixed taps in the middle of the single winding transformer as the voltage variable stage, and switch S _{1 to} S _{n in} series with each fixed tap, respectively. The other side of the switch is connected to one side of the primary side voltage coil 31 of the mutual induction reactor 3, and the other side of the primary side voltage coil 31 is connected to the power ground common line 44. Connect. Each switch may use a device such as a relay or a triac, and the like, and connect the control inputs of each switch to the output terminals 0 to n of the voltage level selector 43. The voltage level selector 43 has a built-in D / A converter and selects each switch stage 0 to n in accordance with the voltage comparison signal level input from the output voltage comparator 4. Thus, several fixed taps installed in the single winding transformer 2 are constituted by an optional fixed tap that can be selected.

The input of the output voltage comparator 4 is connected in parallel with the load output and the output of the output voltage comparator 4 is connected to the A / D input of the voltage level selector 43. In addition, the bypass switch 81 is connected in parallel across the secondary current coil of the mutual induction reactor 3, the input voltage comparison detector 42 is connected in parallel with the power supply, and the output of the input voltage comparison detector 42 is connected. Connect to the input of the OR logic circuit 17 and the output of the OR logic to the input of the zero crossing controller 16, and connect the output of the zero crossing controller 16 to the control input and voltage level selector 43 of the bypass switch 81. Connect to reset input of). In addition, a current detection CT 18 is installed at the output line of the mutual induction reactor 3, the current detection CT output is connected to the input of the current comparator 5, and the output of the output current comparator 5 is connected to another input of OR logic. Connect

The constant voltage control function of the linear power control device of the present invention configured as described above will be described.

When the output voltage V ₂ is lower than the reference voltage set inside the output voltage comparator 4, the output of the output voltage comparator 4 increases and the voltage level selector 43 opens the tap switch of the single winding transformer 2. Since the voltage applied to the primary side voltage coil 31 is lowered by selecting the lower voltage side (Sn → S1), the secondary side current coil voltage Vx is also lowered and the output voltage V ₂ is increased. In addition, when the output voltage V ₂ becomes higher than the reference voltage set inside the output voltage comparator 4, the output of the output voltage comparator 4 is decreased, and the voltage level selector 43 of the single winding transformer 2 By selecting the tap switch to the higher voltage side (S ₁ → S _n ), the voltage applied to the primary side voltage coil 31 is increased to increase the secondary side current coil voltage Vx and decrease the output voltage V ₂ . do.

Thus, the output voltage of the power control device of the invention, _{V 2 = Vs - (V 1} × n 2 / n 1) of which can be summarized as relations, the output voltage (V ₂₎ to the feedback control to actually address of the V ₁ By controlling the current voltage, the large current output voltage (V ₂ ) can be stabilized at a constant level.

Next, the uninterruptible bypass function of the present invention will be described.

In general, when a large amount of current is required in the load 8 such as when the motor is started, or when the input voltage is remarkably reduced, the automatic voltage regulation function provided by the present invention alone does not provide sufficient power to the load 8. It is necessary to bypass the power supply voltage by 100%.

In order to achieve this purpose, if the output current IL detected by the current detection CT 18 increases by more than the reference value set in the output current comparator 5, the output of the output current comparator 5 becomes H state. The zero crossing controller 16 outputs the H signal and turns on the bypass switch 81. At this time, since the zero crossing controller 16 outputs a signal to switch at the O potential of the A.C alternating current, it is possible to minimize electrical noise without causing a spark with the bypass switch 81. In addition, when the input voltage drops below the reference voltage set in the input voltage comparison detector 42, the input voltage detector 42 outputs the H signal, and the OR circuit 17 and the zero crossing controller ( 16) Turn the bypass switch 81 on. At this time, the signal is output to switch at O potential of A.C exchange. As such, when the bypass switch 81 is turned on, the input power voltage is directly connected to the output load 8 without passing through the coil 32.

On the other hand, if a voltage is applied to the primary side voltage coil 31 of the mutual induction reactor 3 while the bypass switch 81 is turned on, a voltage is induced in the secondary side current coil 32 and a short circuit is formed. Will cause a large heat loss. Therefore, the power supply of the primary side voltage coil 31 should be able to be turned off while the bypass switch 81 is turned on. Therefore, this function in the present invention will be described. When the bypass switch 81 input is the H signal, H is applied to the reset input of the voltage level selector 43 so that all outputs of the voltage level selector are reset (selection output stage 0) and the primary voltage control switch ( S ₁ to S _n are all turned off, and the voltage applied to the primary side voltage coil 31 is cut off.

When the bypass switch 81 is turned on in this manner, the power supply 100 can be bypassed to the load 8 with almost no power loss.

On the other hand, when the bypass switch 81 is turned on and the bypass is made, there is a case in which power failure is not possible due to extreme power fluctuations. To prevent this, a resistor 82 and a magnetic 83 are attached between the power supply 100 and the load 8 to prevent sudden power fluctuations so as to bypass the power failure.

As described above, the present invention can not only supply proper power necessary for energy saving but also provide a high-quality average through dual phase control or linear voltage control through a small mutually inductive reactor of about 1/10 of the load power using the principle of linear transformer. It can provide AC voltage, minimize the noise and impact current of switching transient, and can supply constant decompression power to the load by using electromagnetic power converter such as single-circuit transformer and mutual induction reactor of very small size. In addition, the output voltage can be adjusted automatically and the power can be bypassed 100% uninterrupted as needed or automatically, providing a compact, lightweight and reliable low power uninterruptible bypass linear AC power control device.

Claims (1)

A phase comparison controller (1), a voltage variable single winding transformer (2), and a voltage reducing mutual induction reactor (3) are installed at a power input, and a multistage tap is installed in the single winding transformer (2), thereby providing a mutual induction reactor (3). Connect to the switch array (7), install a voltage and current comparator at the power output, connect the output of the output voltage comparator (4) to the switch array control input (S), and compare the phase with the output of the current comparator (5) The logic controller 6 is installed at the output of the controller 1 to operate the switch array 7 by the logic controller 6 to selectively apply the output voltage of the single winding transformer 2 to the mutual induction reactor 3. A plurality of tabs provided between the upper end side 21 and the lower end side 22 of the winding of the single winding transformer 2 are connected to the primary winding of the reactor 3 through the switch array 7 or the switch 71. Connect the start tap and connect the secondary winding of the mutual induction reactor (3) between the power supply (100) and the load (8). The output of the logic controller 6 is connected to the control input S of the switch 71 and the release input C of the switch array 7, and the output of the output voltage comparator 4 is connected to the switch array. 7), the input of the output voltage comparator 4 is connected in parallel with the load output, and the output of the output voltage comparator 4 is connected to the A / D input of the voltage level selector 43. The bypass switch 81 is connected in parallel across the secondary current coil of the mutual induction reactor 3, and the output of the input voltage comparator 4 connected in parallel with the power source is input to the OR logic circuit 17. The output of OR logic to the zero crossing controller 16 input, the control crossing controller 16 output to the control input of the bypass switch 81, the power supply 100 and the load 8 Linear AC power control using phase comparison control, characterized in that by connecting the resistor 82 and the magnetic 83 in series between Device.

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